Modal Propellant Gauging: High-resolution and non-invasive gauging of both settled and unsettled liquids in reduced gravity

Crosby, Kevin; Williams, Nehemiah J.; Werlink, Rudolph J.; Hurlbert, Eric A.

doi:10.1016/j.actaastro.2019.01.050

Cited by 10 publications

(4 citation statements)

References 8 publications

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“…A PZT actuator is a flexible patch that converts the electrical signal to a mechanical energy, or vibration. The signal is amplified by piezo driver modules to an RMS amplitude of 100V [1]. Situated right next to the actuator is a PZT sensor that acts as a "monitor", recording the amplified white noise signal from the actuator.…”

Section: Conceptmentioning

confidence: 99%

Propellant Mass Gauging via Modal Analysis on the International Space Station

Peterson

2022

Proc. Wisc. Space Conf.

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In order for NASA to obtain sustained human presence in space, a higher fuel gauging accuracy is required. Current gauging methods have a sub 5-10% error which requires an additional fuel margin for any rocket or satellite. Doing this increases weight, therefore creating a higher cost. Gauging technologies capable of solving this problem either do not exist or only exist at low Technology Readiness Levels (TRLs). The Modal Propellant Gauging (MPG) project is an effort to develop a higher resolution, light-weight, and cost efficient fuel gauging method for low-gravity environments. MPG uses excited surface acoustic waves on the outside of the tank to measure the tanks resonant frequencies. In microgravity, the liquid will adhere to and coat the inner walls of the tank. The resonant mode frequencies are sensitive to the presence of liquid, meaning the accuracy of MPG is amplified in low-gravity. Modal measurements are taken using sensors adhered to the outer tank walls and a small data acquisition system. A Frequency Response Function (FRF) is then generated to create a reading for a fuel gauge.The newest iteration of MPG is Modal Propellant Gauging - International Space Station (MPG-ISS), which will undergo 30 days of autonomous testing onboard the ISS. This payload will implement MPG onto two tanks separated into two ISS payload lockers. A set amount of liquid will be transferred between both tanks as data is taken on both and stored on the in-flight computer. The MPG-ISS experiment will help validate the use of MPG on future space mission, such as Artemis. This experiment is the next step for MPG to be used on future mission to the Moon and Mars.

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Section: Conceptmentioning

confidence: 99%

Propellant Mass Gauging via Modal Analysis on the International Space Station

Peterson

2022

Proc. Wisc. Space Conf.

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“…The "spectral density" is the Fourier Transform of a correlation function of a stationary, random input signal [1]. For a system defined by a single input signal x(t) and a single output signal y(t) , the spectral densities of the input and output signals S xx(w) and S yy(w) are related via the FRF, H(w), S yy dw…”

Section: Spectral Density Functionmentioning

confidence: 99%

“…In other papers [1] it is shown that the second "moment" of the spectral density for broad-band excitations is related to the modal mass components of a single degree of freedom system that behaves like a set of N coupled, damped linear oscillators through the following:…”

Section: Spectral Density Functionmentioning

confidence: 99%

Spectral Density Method of Liquid Propellant Gauging

Ananda

2020

Proc. Wisc. Space Conf.

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My summer internship experience with NASA Kennedy Space Center’s Advanced Engineering Development Branch focused on collecting and processing data to aid in developing Modal Propellant Gauging (MPG) for use in future Orion/SLS missions. The MPG project is an effort to develop a non-invasive low-cost propellant mass gauging technology for application to existing spacecraft propellant tanks in both low-gravity and earth-loading applications. During my internship I constructed a fuel gauging framework through characterizing the modal signature of a composite-overwrap liquid propellant tank used for testing purposes. I accomplished this through: writing and implementing algorithms that apply broadband white noise signals to piezoelectric actuators adhered to the tank surface, processing acoustic data using Fourier analysis, and producing frequency response functions to experimentally determine resonant modes of the tank structure. A limitation of the current MPG technique is that it does not work in environments with changing pressure; during my internship I also made fundamental contributions to the development of the Spectral Density Propellant Gauging Method, a technique that does not depend on the stiffness of the tank walls.

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“…Recently there has been renewed interest in being able to accurately measure the amount of commodity in a 3D vessel, specifically to determine the amount of propellant left in a fuel tank in orbit, i.e. in 0-G. NASA is exploring several methods to accomplish this including modal analysis [1], acoustic spectral analysis [2], and radio frequency spectral analysis [3] among others. Historically, the most common method to monitor propellant levels has been to assume a given consumption rate by the engines, i.e.…”

Section: Introductionmentioning

confidence: 99%

A derivation of the electrical capacitance tomography sensitivity matrix

Youngquist¹,

Storey²,

Nurge³

et al. 2022

Meas. Sci. Technol.

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The sensitivity matrix, used in electrical capacitance tomography to connect capacitance readings to a dielectric distribution, is derived without assumptions on the magnitude of the relative permittivity and without dropping higher order terms. Deriving this matrix may provide a means to improve the performance of the various published ECT algorithms and extend their applicability to a wider range of dielectric materials.

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Modal Propellant Gauging: High-resolution and non-invasive gauging of both settled and unsettled liquids in reduced gravity

Cited by 10 publications

References 8 publications

Propellant Mass Gauging via Modal Analysis on the International Space Station

Propellant Mass Gauging via Modal Analysis on the International Space Station

Spectral Density Method of Liquid Propellant Gauging

A derivation of the electrical capacitance tomography sensitivity matrix

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